A microfluidic gas damper for stabilizing gas pressure in portable microfluidic systems

Zhang, Xinjie; Zhu, Zhongyi; Xiang, Nan; Zhang, Ni

doi:10.1063/1.4966646

Cited by 17 publications

(6 citation statements)

References 38 publications

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“…In future work, the platform could be improved by replacing the pressure-meter with a flow regulator or stabilizer for more stable and easier sample infusion. 18,52…”

Section: Hand-powered Operationmentioning

confidence: 99%

Fully-automated and field-deployable blood leukocyte separation platform using multi-dimensional double spiral (MDDS) inertial microfluidics

et al. 2020

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“…In future work, the platform could be improved by replacing the pressure-meter with a flow regulator or stabilizer for more stable and easier sample infusion. 18,52…”

Section: Hand-powered Operationmentioning

confidence: 99%

Fully-automated and field-deployable blood leukocyte separation platform using multi-dimensional double spiral (MDDS) inertial microfluidics

et al. 2020

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“…As shown in Figure 2 (A-i), blood is supplied in a pulsatile pattern ( Q b [ t ] = Q α + Q β sin [2π t / T ]) through the inlet. To embody the air compliance effect [ 58 , 59 ], an ACU is attached at the end of the side channel (i.e., outlet [b]). The blood junction pressure is denoted as P j at the junction ( j ) of both channels.…”

Section: Methodsmentioning

confidence: 99%

Biomechanical Assessment of Red Blood Cells in Pulsatile Blood Flows

Kang

2023

Micromachines

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As rheological properties are substantially influenced by red blood cells (RBCs) and plasma, the separation of their individual contributions in blood is essential. The estimation of multiple rheological factors is a critical issue for effective early detection of diseases. In this study, three rheological properties (i.e., viscoelasticity, RBC aggregation, and blood junction pressure) are measured by analyzing the blood velocity and image intensity in a microfluidic device. Using a single syringe pump, the blood flow rate sets to a pulsatile flow pattern (Qb[t] = 1 + 0.5 sin(2πt/240) mL/h). Based on the discrete fluidic circuit model, the analytical formula of the time constant (λb) as viscoelasticity is derived and obtained at specific time intervals by analyzing the pulsatile blood velocity. To obtain RBC aggregation by reducing blood velocity substantially, an air compliance unit (ACU) is used to connect polyethylene tubing (i.d. = 250 µm, length = 150 mm) to the blood channel in parallel. The RBC aggregation index (AI) is obtained by analyzing the microscopic image intensity. The blood junction pressure (β) is obtained by integrating the blood velocity within the ACU. As a demonstration, the present method is then applied to detect either RBC-aggregated blood with different concentrations of dextran solution or hardened blood with thermally shocked RBCs. Thus, it can be concluded that the present method has the ability to consistently detect differences in diluent or RBCs in terms of three rheological properties.

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“…After nitrogen drying, different layers were bonded with the assistance of an oxygen plasma cleaner (PDC-002, Harrick Plasma). It should be noticed that the elastic membrane with a ratio of base to curing agent of 20:1 has a Young’s module of 266 ± 47 kPa, which leads to a large deformation under low actuation pressures. , Therefore, the 20:1 PDMS membrane was used in this work. In order to prepare an ultrathin PDMS membrane, liquid PDMS (Slygard 184, Dow Corning) with a ratio of base to curing agent of 20:1 was spun onto a CAPTON film at 2500 rpm.…”

Section: Methodsmentioning

confidence: 99%

Integrated Microfluidic Handheld Cell Sorter for High-Throughput Label-Free Malignant Tumor Cell Sorting

Jiang

Xiang

2022

Anal. Chem.

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Handheld sample preparation devices are urgently required for point-of-care diagnosis in resource-limited settings. In this paper, we develop a novel handheld sorter with a multifunction integrated microfluidic chip. The integrated microfluidic handheld sorter (μHCS) is composed of three units, including cartridges, shells, and core integrated microchip. The integrated microchip contains two flow regulators for achieving the on-chip regulation of the input flows generated by a low-cost diaphragm pump to the desired flow rates and a spiral inertial microfluidic channel for size-based cell separation. After introducing the conceptual design of our μHCS system, the performances of the separate spiral channel and flow regulator are systematically characterized and optimized, respectively. Finally, the prototype of the μHCS is successfully assembled to separate the malignant tumor cells from the clinical pleural effusions. Our μHCS is simple to use, inexpensive, portable, and compact and can be used for high-throughput label-free separation of rare cells from large volume samples in resource-limited areas.

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A microfluidic gas damper for stabilizing gas pressure in portable microfluidic systems

Cited by 17 publications

References 38 publications

Fully-automated and field-deployable blood leukocyte separation platform using multi-dimensional double spiral (MDDS) inertial microfluidics

Fully-automated and field-deployable blood leukocyte separation platform using multi-dimensional double spiral (MDDS) inertial microfluidics

Biomechanical Assessment of Red Blood Cells in Pulsatile Blood Flows

Integrated Microfluidic Handheld Cell Sorter for High-Throughput Label-Free Malignant Tumor Cell Sorting

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